SEX DIFFERENCES, SEXUAL SELECTION, AND AGEING: AN EXPERIMENTAL EVOLUTION APPROACH

Life-history (LH) theory predicts that selection will optimize the trade-off between reproduction and somatic maintenance. Reproductive ageing and finite life span are direct consequences of such optimization. Sexual selection and conflict profoundly affect the reproductive strategies of the sexes and thus can play an important role in the evolution of life span and ageing. In theory, sexual selection can favor the evolution of either faster or slower ageing, but the evidence is equivocal. We used a novel selection experiment to investigate the potential of sexual selection to influence the adaptive evolution of age-specific LH traits. We selected replicate populations of the seed beetle Callosobruchus maculatus for age at reproduction ("Young" and "Old") either with or without sexual selection. We found that LH selection resulted in the evolution of age-specific reproduction and mortality but these changes were largely unaffected by sexual selection. Sexual selection depressed net reproductive performance and failed to promote adaptation. Nonetheless, the evolution of several traits differed between males and females. These data challenge the importance of current sexual selection in promoting rapid adaptation to environmental change but support the hypothesis that sex differences in LH—a historical signature of sexual selection—are key in shaping trait responses to novel selection.     

Molekulare und., adaptive Evolution, Kladistik und Stammesgeschichte1: Ergänzungen zu einer Arbeitshypothese

Molecular and “adaptive” evolution, cladistic and phylogeny. Supplementations to a working hypothesis The methods of molecular biology and morpholo for the taxonomical assessment have given in several cases very different results. The following examples are discussed: Ailuropoda melanoleuca as an ursoid member of the Carnivora (Ursidae or Ailuropodidae?), Homo saiens and his position to the African apes (Pan and Gorilla) (Pongidae or Hominidae?), Theroipithecus gelada and its affinities to the baboons (Papionini or Theropithecini ?) and Oreopithecus bambolii from the late Miocene of Italy and its taxonomical position within the catarrhine primates. For the three extant species not only the “two level evolution” (molecular and morphological-adaptative evolution) is evident, but also the working hypothesis, that the “adaptative” evolution is more rapidly as the molecular evolution, as the author is suggesting since 1969. The results of molecular methods (immunoloy, amino acid sequences, electrophoresis, DNA-DNA hybridization) are more important for the phylogeny than for the taxonomy. For the cladistic method it is clear, that a cladogram is not a phylogenetic tree, as suggested Peter Ax (1984).     

PHYLOGENETIC ANALYSIS OF THE MARINE AND FRESHWATER THALAS-SIOSIROID DIATOMS

The thalassiosiroid centric diatoms are distinguished by at least one synapomorphy, the strutted process or fultoportula. Variously classified as a family (Thalassiosiraceae) or an order (Thalassiosirales) among centric diatoms, it is generally conceded that the group of several hundred fossil and living species is monophyletic as a whole. There are two ecological groups of thalassiosiroids, marine and freshwater. It has been hypothesized, based on an ecletic, non-rigorous, evolutionary taxonomy perspective that both the marine and freshwater ecological groups are also monophyletic, but this hypothesis has never been tested in a rigorous framework. Likewise, the freshwater thalassiosiroid species have been grouped into several genera and subgenera using an evolutionary taxonomic approach, but these hypotheses have not fully been tested using cladistic analysis. Focusing mainly on freshwater species, but including at least one representative of each marine genus and one representative from each of several proposed subgeneric groupings of the genus Thalassiosira , we scored morphological characters for fossil and living marine and freshwater Thalassiosiraceae to test these hypotheses. Our cladistic results provide strong support for monophyly for the freshwater group, but it seems unlikely that the marine group is monophyletic. The cladistic results are corroborated to greater or lesser degrees by the fossil record. The implications for evolution in the group and for taxon sampling in molecular studies we are conducting will be discussed.     

The evolution of marine insects: phylogenetic, ecological and geographical aspects of species diversity in marine water striders

No other group of insects have been more successful in colonizing marine habitats than water striders and their allies (Heteroptera, Gerromorpha). More than 10% of the 1700 species of gerromorphan bugs are marine. Water striders have colonized the marine environment at least 14 times. The fossil records suggest that marine habitats were invaded by members of the families Veliidae and Gerridae earlier than 20-30 and 45 million years before present, respectively. Estuaries and mangrove swamps are undoubtedly the ancestral type of habitat, but water striders have diversified further in marine habitats including the surface of the open ocean (sea skaters. Halobates). Except for being obligatorily flightless, marine water striders are structurally very similar to their non-marine relatives. Physiological and behavioral rather than morphological specializations are likely to have been key innovations in the transition from limnic to marine habitats. The oldest and most species-rich clades originated in the Indo-West Pacific region. There are 3.5 times as many species of marine water striders in the Indo-West Pacific region than in the Atlantic/Caribbean/East Pacific region. This "diversity anomaly" is explained historically by region-specific differences in the origin and proliferation of clades, in paleoclimate and paleogeography, and in the propensity for dispersal between regions.     

Molecular phylogeny of Harpactorini (Insecta: Reduviidae): correlation of novel predation strategy with accelerated evolution of predatory leg morphology

Much research and discussion have focused on the effects of key innovations on lineage diversification, whereas little has been done to investigate their role in morphological evolution using phylogenetic approaches. Here we present the first comprehensive molecular phylogeny of the Harpactorini (Insecta: Reduviidae), the largest assassin bug tribe, sampling 229 terminal taxa and using five gene segments (28S D2, D3–D5, 16S, COI, and Deformed). Employing comparative phylogenetic methods, we demonstrate the correlation of a putative key innovation, the sticky trap predation strategy, with accelerated rates of morphological evolution of the predatory fore leg in assassin bugs. We show that bugs exhibiting sticky trap predation have evolved more slender and longer fore femora than non‐sticky bugs. Using phylogenetically independent contrast analyses, we document correlated evolution between femoral thickness and length. We argue that the novel sticky trap predation strategy may allow sticky bugs to alleviate functional constraints on the fore femur and thus to attain a higher rate of evolution than other Harpactorini or Reduviidae. We discuss the possibility that sticky bugs represent a case of adaptive radiation. We also test historical supra‐generic groups within the Harpactorini, and show that most of them are not monophyletic. We confirm the paraphyly of Harpactorini with respect to Rhaphidosomini.     

Selection in a fluctuating environment and the evolution of sexual dimorphism in the seed beetle Callosobruchus maculatus

Temperature changes in the environment, which realistically include environmental fluctuations, can create both plastic and evolutionary responses of traits. Sexes might differ in either or both of these responses for homologous traits, which in turn has consequences for sexual dimorphism and its evolution. Here, we investigate both immediate changes in and the evolution of sexual dimorphism in response to a changing environment (with and without fluctuations) using the seed beetle Callosobruchus maculatus. We investigate sex differences in plasticity and also the genetic architecture of body mass and developmental time dimorphism to test two existing hypotheses on sex differences in plasticity (adaptive canalization hypothesis and condition dependence hypothesis). We found a decreased sexual size dimorphism in higher temperature and that females responded more plastically than males, supporting the condition dependence hypothesis. However, selection in a fluctuating environment altered sex-specific patterns of genetic and environmental variation, indicating support for the adaptive canalization hypothesis. Genetic correlations between sexes (r(MF) ) were affected by fluctuating selection, suggesting facilitated independent evolution of the sexes. Thus, the selective past of a population is highly important for the understanding of the evolutionary dynamics of sexual dimorphism.     

Combining molecular and morphological analyses of water strider phylogeny (Hemiptera–Heteroptera, Gerromorpha): effects of alignment and taxon sampling

Abstract. The semiaquatic bugs (Hemiptera–Heteroptera, infraorder Gerromorpha), comprising water striders and their allies (c. 1900 described species), are familiar inhabitants of water surfaces in all continents. Recent fossil evidence indicates that the evolutionary history of semiaquatic bugs spans more than 120 million years of geological time. At present, our insight into the phylogeny of higher taxa is based upon Andersen's manual cladistic analysis of a suite of morphological characters. The present work expands the phylogenetic insight with numerical cladistic analyses of morphological and molecular datasets (partial sequences of 16S and 28S rDNA) for forty species of Gerromorpha covering most higher taxa (families, subfamilies), estimates of branch support, character incongruence, and topological congruence (nodal stability). For the molecular data we apply different alignment options (manual vs numerical alignment; multiple alignment vs direct optimization), treat insertion–deletion events (indels) as either missing data or as a fifth character state, subject the data to a sensitivity analysis, and estimate topological congruence between different analysis trees. Relationships change considerably under different analysis conditions, which means that there is little node stability, and for selecting preferred analysis conditions there is conflicting evidence from rescaled incongruence length difference and the key node criterion. Based on the analysis of the combined morphological and molecular datasets, this study supports the close relationship between the families Gerridae, Hermatobatidae and Veliidae (superfamily Gerroidea), but not the monophyly of the family Veliidae. The results suggest that the genus Ocellovelia (Ocelloveliinae) should be excluded from this family and placed as a sister group to Gerridae + the remaining species of Veliidae. Our study also supports a close relationship between the subfamilies Halobatinae and Ptilomerinae (Gerridae), and that the subfamily Veliinae is probably nonmonophyletic.     

Cladistic analysis of Reduviidae (Heteroptera: Cimicomorpha) based on morphological characters

Abstract.  With more than 6600 species worldwide, Reduviidae (Insecta: Heteroptera), or assassin bugs, form the second largest and one of the most diverse groups of true bugs. The poor condition of the higher-level classification of Reduviidae is reflected by the facts that different authors recognize between 21 and 32 subfamily-level names and that Reduviidae were never subjected to a rigorous cladistic analysis using an exemplar approach. In the present study, a cladistic analysis of higher-level taxa of Reduviidae based on 162 morphological characters and 75 ingroup and outgroup species is presented. Twenty-one subfamily-level taxa of Reduviidae were examined, accounting for 28 tribes. In addition to characters previously used for diagnosis in Reduviidae, information on recently published character complexes is used in the present analysis, supplemented with new character information gathered specifically for this project. Reduviidae are supported as a monophyletic group with Pachynomidae as their sister taxon. The major results of this study are the support of a sistergroup relationship of Hammacerinae with the remaining Reduviidae, the monophyly of the Phymatine Complex, the relatively basal position of Harpactorinae within Reduviidae as well as a novel hypothesis on the relationships within this group, and the sistergroup relationship of Ectrichodiinae + Tribelocephalinae and their placement in a clade that also contains Emesinae, Saicinae, and Visayanocorinae. The analysis further supports a clade formed by paraphyletic Salyavatinae + Sphaeridopinae, renders Vesciinae non-monophyletic, and demonstrates the polyphyly of Reduviinae. Pseudocetherinae are shown to group with some Reduviinae. Triatominae are supported as a monophyletic group and are nested among additional Reduviinae and Stenopodainae.     

Flatfishes, Turtles, and Bolyerine Snakes: Evolution by Small Steps or Large, or Both?

Step size in evolution is rapidly becoming a major subject of interest to biologists. Traditionally, small changes alone were seen as significant in evolution, and any large differences between an ancestor and its descendant could be explained entirely by the accumulation of many small steps. Whether the evolution of major adaptations is mainly a matter of amassing such small increments of change, or if a significant proportion occurs through the inclusion of one or more large steps, is vital to the understanding of how evolution works. This paper begins by examining four “classic” examples of animals—flatfishes, turtles, bolyerine snakes, and gastropod molluscs—each of which has seemed difficult to interpret as resulting from a continuous series of tiny increments. Recently, however, arguments have appeared to contradict those views, and to propose instead that each of these animal groups arose through continuous adaptive modifications. While some of these arguments are more plausible than others, the view of the present author is that in none of them is there convincing evidence to conclude that the groups arose solely through gradual changes. More specifically, there is no basis to reject an evolutionary origin of the major traits in each group that included at least one principal inovation, occurring in a large, discontinuous step, preceded and followed by relatively small, more gradual changes. The broader question of how discontinuous evolution may occur is addressed through several means. These include considerations of epigenetic (sensu Waddington) development, comparative embryology, population genetics, and other approaches. Overall the phenomenon of adaptive accommodation is seen as of major importance, and its implications for ameliorating possible deleterious attributes of novel phenotypes are discussed. In the course of these analyses the doctrine that all adaptive evolution is driven by external environmental change is reviewed. It is suggested that while small adaptive changes are often closely related to shifts in specific environmental facets, the modifications associated with more major adaptations may be less so.     

A CLADISTIC TEST OF THE TAXON CYCLE AND TAXON PULSE HYPOTHESES

Abstract— A species' habitat preference is intcrpretablc both as a response to present-day conditions and as a result of evolutionary response to historical conditions. The taxon cycle and taxon pulse have been proposed as hypotheses that allow prediction of patterns of habitat specialization within a lineage. Both are based on common assumptions: (1) habitat specialization is largely irreversible in a lineage, (2) ecological specializations arise in a center of origin, and (3) dispersal events leading to current distributions can be ascertained. Eight taxa of Antillean, Mexican, and Central American Carabidae, for which cladistic hypotheses of relationship have been proposed, are used to test the generality of the taxon cycle and pulse. The patterns of habitat utilization predicted by the taxon cycle and taxon pulse hypotheses are tested by comparing cladistic transformations of habitat preference to randomly generated patterns of data generated under a null hypothesis. Evolutionary changes in habitat are interpreted using Camin-Sokal coding, which assumes irreversible habitat shifts and a predetermined ecological ground state (assumptions of the taxon cycle and taxon pulse). An observed pattern is considered to demonstrate the taxon cycle or pulse when it results in an explanation of the habitat shifts that is more parsimonious than 95 % of the randomly generated patterns. Of the eight carabid groups, only one exhibits a statistically significant pattern supporting the taxon cycle and pulse. The failure of the taxon cycle and pulse as generally predictive hypotheses may be due to historical changes in climate that permit episodes of range expansion for species previously restricted to small ranges, and habitat shifts and specialization that do not progress in a linear transformation series. Habitat shifts are also analyzed using Farris optimization, resulting in the most parsimonious transformation series of habitats, subject to a predefined ordering of habitats, while allowing reversals. Significance of an observed pattern of habitat shifts under Farris optimization implies habitat constancy relative to cladogenesis, and step-wise changes in habitat preference. Two of the eight groups exhibit significant patterns of habitat utilization under Farris optimization, indicating that vicariance of areas of like habitat has been the predominant factor generating species diversity in these groups. The other groups do not exhibit habitat constancy, suggesting rapid changes in habitat preference relative to speciation.     

Distribution of water bugs (Heteroptera: Nepomorpha, Gerromorpha) over latitudinal zones in the northeast of European Russia

Data on the taxonomic composition of water bugs (Heteroptera: Nepomorpha, Gerromorpha) in the northeast of European Russia are given. A total of 34 water-bug species, which belong to 16 genera and 8 families, are recorded. The species diversity of Nepomorpha and Gerromorpha changes northwards: 33 occur in the taiga zone and only 8 species occur in the tundra zone. The bulk of the fauna consists of Eurosiberian (29%) and trans-Eurasian (26%) species; in latitude-related terms, the temperate group is most richly represented (64%). The species composition of the aquatic and semiaquatic heteropteran fauna of the region is especially similar to that of the tundra and taiga zones of Western Siberia.     

AERODYNAMICS,THERMOREGULATION, AND THE EVOLUTION OF INSECT WINGS: DIFFERENTIAL SCALING AND EVOLUTIONARY CHANGE

We examine several aerodynamic and thermoregulatory hypotheses about possible adaptive factors in the evolution of wings from small winglets in insects. Using physical models of Paleozoic insects in a wind tunnel, we explore the potential effects of wings for increasing gliding distance, increasing dispersal distance during parachuting, improving attitude control or stability, and elevating body temperatures during thermoregulation. The effects of body size and shape, wing length, number, and venation, and meteorological conditions are considered. Hypotheses consistent with both fixed and moveable wing articulations are examined. Short wings have no significant effects on any of the aerodynamic characteristics, relative to wingless models, while large wings do have significant effects. In contrast, short wings have large thermoregulatory effects relative to wingless models, but further increases in wing length do not significantly affect thermoregulatory performance. At any body size, there is a wing length below which there are significant thermoregulatory effects of increasing wing length, and above which there are significant aerodynamic effects of increasing wing length. The relative wing length at which this transition occurs decreases with increasing body size. These results suggest that there could be no effective selection for increasing wing length in wingless or short-winged insects in relation to increased aerodynamic capacity. Our results are consistent with the hypothesis that insect wings initially served a thermoregulatory function and were used for aerodynamic functions only at larger wing lengths and/or body sizes. Thus, we propose that thermoregulation was the primary adaptive factor in the early evolution of wings that preadapted them for the subsequent evolution of flight. Our results illustrate an evolutionary mechanism in which a purely isometric change in body size may produce a qualitative change in the function of a given structure. We propose a hypothesis in which the transition from thermoregulatory to aerodynamic function for wings involved only isometric changes in body size and argue that changes in body form were not a prerequisite for this major evolutionary change in function.     

Temporal environmental variation and phenotypic plasticity: a mechanism underlying priority effects

Understanding the role of history in the formation of communities has been a major challenge in community ecology. Here, we explore the role of phenotypic plasticity and its associated trait‐mediated indirect interactions as a mechanism behind priority effects. Using organisms with inducible defenses as a model system, we examine how aquatic communities initially containing different predator environments are affected at the individual and community level by the colonization of a second predator. Snails and tadpoles were established in four different caged‐predator environments (no predator, fish, crayfish or water bugs). These four communities were then crossed with three predator colonization treatments (no colonization, early colonization, or late colonization) using lethal water bugs as the predator. The snails responded to the caged predator environments with predator‐specific behavioral and morphological defenses. In the colonization treatments, snails possessing the wrong phenotype attempted to induce phenotypic changes to defend themselves against the new risk. However, snails initially induced by a different predator environment often suffered high predation rates. Hence, temporal variation in predation risk not only challenged the snail prey to try to track this environmental variation through time by adjusting their defensive phenotypes, but also caused trait‐mediated interactions between snails and the colonizing predator. For tadpoles within these communities, there was little evidence that the morphological responses of snails indirectly effected tadpole predation rates by colonizing water bugs. Unexpectedly, predation rates on tadpoles by colonizing water bugs were generally higher in the three caged‐predator treatments, suggesting that water bugs elevated their foraging activity in response to potentially competing predators. In summary, we demonstrate an important priority effect in which the initial occurrence of one species of predator can facilitate predation by a second predator that colonizes at a later date (i.e. a TMII) suggesting that phenotypic plasticity can be an important driver behind priority effects (i.e. historical exposure to predators).     

鲤科鲌亚科鱼类的系统发育及动物地理学

以雅罗鱼亚科为外群,采用分支系统学的原理和方法对鲌亚科17个属(须鳊属除外)进行了系统发育和动物地理学的分析.结果表明,(1)鲌亚科这17个属为一个单系群,并由4个较小的单系群组成;(2)鲌亚科现在的地理分布格局除源自离散事件外,主要源于扩散事件.鲌亚科的特征演化还表明,东亚地区地质历史的反转演化和平行演化可能在鲌亚科系统发育过程中起了重要的作用.     

Establishment of aromorphic organization: Causes and conditions

Aromorphoses appear based on specialization of ancestral taxon in a narrow adaptive zone. Aromorphic evolution is accumulation and coordination of particular adaptive changes in organismic organization, which provide adaptation to the whole range of environmental conditions in the initial adaptive zone. This provides preadaptation of a taxon to the expansion of the adaptive zone. A distinctive feature of aromorphosis is preservation of fitness in both ancestral and newly acquired adaptive zones. Therefore, aromorphoses are retained during subsequent phylogeny and lost only in the case of very strong, usually hypomorphic specialization.     

ORIGIN AND EVOLUTION OF CONTINENTAL BIOTAS: SPECIATION AND HISTORICAL CONGRUENCE WITHIN THE AUSTRALIAN AVIFAUNA

Factors governing the origin and evolution of continental biotas were investigated using an analysis of speciation patterns within the Australian avifauna. Phylogenetic relationships within seven lineages of birds were analyzed by numerical cladistic techniques applied to data sets of morphological characters. These relationships revealed extensive congruence among the spatial and temporal histories of lineages whose species are endemic to common areas of endemism. A general hypothesis is constructed to explain this congruence in which widespread biotas are postulated to have been partitioned into areas of endemism by the origin of geomorphological and/or ecological-climatic barriers. Congruence in these phylogenetic patterns of differentiation suggests the following historical pattern of interrelationships for areas of endemism along the northern and eastern coasts of Australia: (Kimberley Plateau + Arnhem Land) + ([New Guinea + Cape York Peninsula] + [Atherton Plateau + Eastern Coastal Rainforest]). Likewise, this study indicates that the arid interior avifauna was segregated into two closely related biotas (Eastern and Western Desert biotas) by the Eyrean Barrier. These biotas are, in turn, related to a more mesic avifauna that was itself subdivided into areas of endemism located in the Southwest and Southeast corners of the continent.     

Adaptive amplification: an inducible chromosomal instability mechanism

Adaptive mutation is an induced response to environmental stress in which mutation rates rise, producing permanent genetic changes that can adapt cells to stress. This contrasts with neo-Darwinian views of genetic change rates blind to environmental conditions. DNA amplification is a flexible, reversible genomic change that has long been postulated to be adaptive. We report the discovery of adaptive amplification at the lac operon in Escherichia coli. Additionally, we find that adaptive amplification is separate from, and does not lead to, adaptive point mutation. This contradicts a prevailing alternative hypothesis whereby adaptive mutation is normal mutability in amplified DNA. Instead, adaptive mutation and amplification are parallel routes of inducible genetic instability allowing rapid evolution under stress, and escape from growth inhibition.     

Intertidal mussel beds from the South-western Atlantic show simple structure and uniform appearance: does environmental harshness explain the community?

Communities of the rocky mid-intertidal zone of the South-western Atlantic are uniform in appearance, dominated by dense monocultures of small-size mussels (Brachidontes rodriguezii and Perumytilus purpuratus). To explain this, two hypotheses have been advanced in the literature: environmental harshness due to high potential evaporation and historical contingency after the Last Glacial Maximum. In this study of Uruguayan and Argentine shores, we address the implications and predictions of these two hypotheses from a biogeographic perspective by studying the regional distribution and composition of mid-intertidal mussels. We conducted an extensive latitudinal sampling survey (21 locations, 34–54°S), along with a compilation of available information on mussel bed composition and mussel predators present along the coastline. Then we constructed latitudinal profiles of ecologically significant environmental variables with specific emphasis on potential evaporation, a proxy for desiccation stress. The results show that mussel beds are composed of two species of small mussels, which coexist over a biogeographic transition zone (40–42°S) related to sea surface water temperature. The distribution of mussels along the coastline studied is not consistent with the environmental harshness hypothesis. In addition, in the Central Patagonian zone (44–50°S), two invertebrate predators also inhabit the intertidal rocky shores. However, these localities showed higher environmental harshness (potential evaporation rate) than non-Patagonian localities. We suggest that further attention should be given to historical contingency in order to advance towards a hypothesis consistent with current knowledge on the post-glacial biogeographic history of the South-western Atlantic.     

Comparative biology and the importance of cladistic classification: a case study from the sensory biology of squamate reptiles

Evolutionary taxonomy has all but succumbed to cladistic methodology, but it continues to exert considerable influence in the realm of higher classification. Some systematists accept cladistic methods in phylogeny inference, but allow paraphyly in formal classifications. Most important, however, many traditional classifications based on paraphyletic groups (e.g. 'Reptilia') remain in force, deeply entrenched in the literature. Cladists have argued that such paraphyletic classifications can mislead comparative biologists into false evolutionary generalizations, but this assertion has rarely, if ever, been supported by example. This paper provides a case study, illustrating in detail the influence of a traditional paraphyletic classification of squamate reptiles on the historical development of ideas regarding the evolution of sensory modes (chemoreception vs. vision) in the group. The paraphyletic classification is shown to have led to false generalizations and incorrect conclusions stemming directly from the fact that the classification did not reflect accurately the phylogeny of Squamata, particularly the cladistic relationships of Gekkota. This study provides direct evidence that evolutionary generalization must be rooted in the branching pattern of phylogeny and not the potentially arbitrary categorical ranks of traditional taxonomies. It further supports recent calls for a truly phylogenctic taxonomy that has as its philosophical core the concept of descent.     

Evolution of wing polymorphism and genital asymmetry in the thread‐legged bugs of the tribe Metapterini Stål (Hemiptera,Reduviidae, Emesinae) based on morphological characters

Wing polymorphism and asymmetric male genitalia are intriguing morphological phenomena occurring in insects. Among Emesinae, or thread‐legged bugs, the tribe Metapterini Stål exhibits these two interesting morphological attributes. Nonetheless, evolutionary interpretations of these phenomena cannot be put forward because phylogenetic hypotheses for Emesinae are lacking. Thread‐legged bugs are easily recognized among assassin bugs due to their elongated and seemingly delicate body. The tribe Metapterini has 28 genera and approximately 280 described species. The only available phylogenetic hypothesis among Emesinae tribes was proposed by Wygodzinsky (1966), and it hypothesized Deliastini Villiers as the sister group of Metapterini, although this hypothesis has never been tested with cladistic approaches. Recent analyses using character sets of genitalia and prolegs suggest that Metapterini might not be monophyletic. In order to test these ideas, we compiled a morphological dataset of 138 characters that includes external morphological characters, detailed features of prolegs and genitalia of both sexes for Metapterini, which were analysed cladistically including 55 terminals, comprising 24 genera (85.7% of the generic diversity), 43 species of Metapterini and 12 outgroups. Metapterini was recovered as paraphyletic by the inclusion of Bergemesa Wygodzinsky, Palacus Dohrn and Stalemesa Wygodzinsky, all currently assigned to Deliastini. Gardena Dohrn (Emesini) was recovered as the sister group of Metapterini + Deliastini as suggested by Wygodzinsky (1966). Based on these results, we synonymize Deliastini syn. n. with Metapterini sensu n. and propose two new genera: Bacata Castro‐Huertas & Forero gen. n. , for three Andean species previously placed in Liaghinella Wygodzinsky, and Valkyriella Castro‐Huertas & Forero gen. n. for Ghilianella borgmeieri Wygodzinsky. Ancestral state reconstruction of wing polymorphism indicates that males and females were fully winged in the ancestor of Metapterini sensu n. with two independent evolutionary transitions to the apterous and brachypterous conditions. The analysis of the symmetry of the male genitalia shows an ancestor with symmetric male genitalia and two independent emergences of asymmetrical male genitalia in Metapterini.